Linked e-resources
Details
Table of Contents
Chapter 1: Fundamentals of Luminescent Materials; 1.1 Fundamentals of Luminescence; 1.1.1 Absorption; 1.1.2 Emission; 1.1.2.1 Pure Electronic Transitions; 1.1.2.2 Franck-Condon Principle; 1.1.3 Afterglow; 1.2 Inorganic Afterglow Phosphors; 1.2.1 Band Structure of Inorganic Host; 1.2.2 Energy Levels of Isolated Ions in Solids; 1.2.2.1 Hamiltonian of the Energy State of a Multi-electron Ion; 1.2.2.2 Term Symbols; 1.2.2.3 Energy Levels in Solid State; 1.2.3 Luminescent Centers; 1.2.3.1 Trivalent Lanthanide Ions; 1.2.3.2 Divalent Lanthanide Ions; 1.2.3.3 Transition Metal Ions
1.2.4 Influence of Defects and ImpuritiesReferences; Chapter 2: Inorganic Long Persistent Phosphor; 2.1 Introduction; 2.2 Classification of Inorganic Long Persistent Phosphors; 2.2.1 Lanthanide-Activated Phosphor; 2.2.1.1 Eu2+-Activated Phosphor; 2.2.1.2 Lanthanide Ions Other than Eu2+; 2.2.1.3 Summary; 2.2.2 Transition Metal-Activated Persistent Phosphor; 2.2.2.1 Mn2+-Activated Phosphor; 2.2.2.2 Cr3+-Activated Phosphor; 2.2.3 Summary; 2.3 Synthetic Strategies; 2.3.1 High-Temperature Solid-State Reaction; 2.3.2 Sol-Gel Processing; 2.3.3 Combustion Technique; 2.3.4 Hydrothermal Treatment
2.3.5 Other Emerging Methods2.3.6 Summary; 2.4 Optical Properties; 2.5 Commercially Available Long Persistent Phosphor; 2.6 Factors Affecting Afterglow Properties; 2.6.1 Emitting ion; 2.6.2 Host; 2.6.3 Codopant; 2.6.4 Fluxing Agent; 2.6.5 Preparation Condition; 2.7 Surface Modification; 2.7.1 Inorganic Coating; 2.7.2 Small Molecule Modification; 2.7.3 Polymer Modification; 2.7.3.1 Physical Coating; 2.7.3.2 Chemical Coating; References; Chapter 3: Material Characterizations; 3.1 Optical Properties; 3.1.1 Excitation and Emission; 3.1.2 Reflection and Absorption; 3.1.3 Thermoluminescence
3.1.4 Luminescence Decay3.2 Structural Characteristics; 3.2.1 Size and Morphology; 3.2.2 Crystal Structure; References; Chapter 4: Applications of Inorganic Afterglow Phosphors; 4.1 Display and Lighting; 4.1.1 Fire Safety Signs; 4.1.2 Road Traffic Signs; 4.1.3 Luminous Watch; 4.1.4 Luminous Fibers; 4.2 Biological Applications; 4.2.1 In Vivo Imaging; 4.2.2 Molecular Sensing; 4.2.2.1 Homogeneous FRET Assay; 4.2.2.2 Homogeneous Reaction Assay; 4.2.3 Lateral Flow Assay; References; Chapter 5: Organic Afterglow Phosphors; 5.1 Principle of Organic Luminescence; 5.1.1 Fluorescence
5.1.2 Phosphorescence5.1.3 Thermally Activated Delayed Fluorescence (TADF); 5.1.4 Hybridized Local and Charge Transfer; 5.1.5 Triplet-Triplet Annihilation and Singlet Fission; 5.1.6 Organic Ultra-long Room-Temperature Phosphorescence (OURTP); 5.2 Materials for Organic Afterglow; 5.2.1 Single-Component Small Molecules; 5.2.2 Multicomponent Materials; 5.2.3 Polymers; 5.2.4 Carbon Dots; 5.2.5 Metal-Organic Frameworks (MOFs); 5.2.6 Complexes; 5.3 Applications of Organic Afterglow Phosphors; 5.3.1 Afterglow OLEDs; 5.3.2 Anti-counterfeiting; 5.3.3 Optical Recording; 5.3.4 Sensors; 5.3.5 Bioimaging
1.2.4 Influence of Defects and ImpuritiesReferences; Chapter 2: Inorganic Long Persistent Phosphor; 2.1 Introduction; 2.2 Classification of Inorganic Long Persistent Phosphors; 2.2.1 Lanthanide-Activated Phosphor; 2.2.1.1 Eu2+-Activated Phosphor; 2.2.1.2 Lanthanide Ions Other than Eu2+; 2.2.1.3 Summary; 2.2.2 Transition Metal-Activated Persistent Phosphor; 2.2.2.1 Mn2+-Activated Phosphor; 2.2.2.2 Cr3+-Activated Phosphor; 2.2.3 Summary; 2.3 Synthetic Strategies; 2.3.1 High-Temperature Solid-State Reaction; 2.3.2 Sol-Gel Processing; 2.3.3 Combustion Technique; 2.3.4 Hydrothermal Treatment
2.3.5 Other Emerging Methods2.3.6 Summary; 2.4 Optical Properties; 2.5 Commercially Available Long Persistent Phosphor; 2.6 Factors Affecting Afterglow Properties; 2.6.1 Emitting ion; 2.6.2 Host; 2.6.3 Codopant; 2.6.4 Fluxing Agent; 2.6.5 Preparation Condition; 2.7 Surface Modification; 2.7.1 Inorganic Coating; 2.7.2 Small Molecule Modification; 2.7.3 Polymer Modification; 2.7.3.1 Physical Coating; 2.7.3.2 Chemical Coating; References; Chapter 3: Material Characterizations; 3.1 Optical Properties; 3.1.1 Excitation and Emission; 3.1.2 Reflection and Absorption; 3.1.3 Thermoluminescence
3.1.4 Luminescence Decay3.2 Structural Characteristics; 3.2.1 Size and Morphology; 3.2.2 Crystal Structure; References; Chapter 4: Applications of Inorganic Afterglow Phosphors; 4.1 Display and Lighting; 4.1.1 Fire Safety Signs; 4.1.2 Road Traffic Signs; 4.1.3 Luminous Watch; 4.1.4 Luminous Fibers; 4.2 Biological Applications; 4.2.1 In Vivo Imaging; 4.2.2 Molecular Sensing; 4.2.2.1 Homogeneous FRET Assay; 4.2.2.2 Homogeneous Reaction Assay; 4.2.3 Lateral Flow Assay; References; Chapter 5: Organic Afterglow Phosphors; 5.1 Principle of Organic Luminescence; 5.1.1 Fluorescence
5.1.2 Phosphorescence5.1.3 Thermally Activated Delayed Fluorescence (TADF); 5.1.4 Hybridized Local and Charge Transfer; 5.1.5 Triplet-Triplet Annihilation and Singlet Fission; 5.1.6 Organic Ultra-long Room-Temperature Phosphorescence (OURTP); 5.2 Materials for Organic Afterglow; 5.2.1 Single-Component Small Molecules; 5.2.2 Multicomponent Materials; 5.2.3 Polymers; 5.2.4 Carbon Dots; 5.2.5 Metal-Organic Frameworks (MOFs); 5.2.6 Complexes; 5.3 Applications of Organic Afterglow Phosphors; 5.3.1 Afterglow OLEDs; 5.3.2 Anti-counterfeiting; 5.3.3 Optical Recording; 5.3.4 Sensors; 5.3.5 Bioimaging